源码来自于nlp-tutorial,我在其基础上进行了修改
代码语言:javascript复制'''
code by Tae Hwan Jung(Jeff Jung) @graykode, modify by wmathor
6/11/2020
'''
import torch
import numpy as np
import torch.nn as nn
import torch.optim as optim
import matplotlib.pyplot as plt
import torch.utils.data as Data
dtype = torch.FloatTensor
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")文本预处理
代码语言:javascript复制sentences = ["jack like dog", "jack like cat", "jack like animal",
"dog cat animal", "banana apple cat dog like", "dog fish milk like",
"dog cat animal like", "jack like apple", "apple like", "jack like banana",
"apple banana jack movie book music like", "cat dog hate", "cat dog like"]
word_sequence = " ".join(sentences).split() # ['jack', 'like', 'dog', 'jack', 'like', 'cat', 'animal',...]
vocab = list(set(word_sequence)) # build words vocabulary
word2idx = {w: i for i, w in enumerate(vocab)} # {'jack':0, 'like':1,...}模型相关参数
代码语言:javascript复制# Word2Vec Parameters
batch_size = 8
embedding_size = 2 # 2 dim vector represent one word
C = 2 # window size
voc_size = len(vocab)数据预处理
代码语言:javascript复制# 1.
skip_grams = []
for idx in range(C, len(word_sequence) - C):
center = word2idx[word_sequence[idx]] # center word
context_idx = list(range(idx - C, idx)) list(range(idx 1, idx C 1)) # context word idx
context = [word2idx[word_sequence[i]] for i in context_idx]
for w in context:
skip_grams.append([center, w])
# 2.
def make_data(skip_grams):
input_data = []
output_data = []
for i in range(len(skip_grams)):
input_data.append(np.eye(voc_size)[skip_grams[i][0]])
output_data.append(skip_grams[i][1])
return input_data, output_data
# 3.
input_data, output_data = make_data(skip_grams)
input_data, output_data = torch.Tensor(input_data), torch.LongTensor(output_data)
dataset = Data.TensorDataset(input_data, output_data)
loader = Data.DataLoader(dataset, batch_size, True)假设所有文本分词,转为索引之后的list如下图所示
根据论文所述,我这里设定window size=2,即每个中心词左右各取2个词作为背景词,那么对于上面的list,窗口每次滑动,选定的中心词和背景词如下图所示
那么skip_grams变量里存的就是中心词和背景词一一配对后的list,例如中心词2,有背景词0,1,0,1,一一配对以后就会产生[2,0],[2,1],[2,0],[2,1]。skip_grams如下图所示
由于Word2Vec的输入是one-hot表示,所以我们先构建一个对角全1的矩阵,利用np.eye(rows)方法,其中的参数rows表示全1矩阵的行数,对于这个问题来说,语料库中总共有多少个单词,就有多少行
然后根据skip_grams每行第一列的值,取出相应全1矩阵的行。将这些取出的行,append到一个list中去,最终的这个list就是所有的样本X。标签不需要one-hot表示,只需要类别值,所以只用把skip_grams中每行的第二列取出来存起来即可
最后第三步就是构建dataset,然后定义DataLoader
构建模型
代码语言:javascript复制# Model
class Word2Vec(nn.Module):
def __init__(self):
super(Word2Vec, self).__init__()
# W and V is not Traspose relationship
self.W = nn.Parameter(torch.randn(voc_size, embedding_size).type(dtype))
self.V = nn.Parameter(torch.randn(embedding_size, voc_size).type(dtype))
def forward(self, X):
# X : [batch_size, voc_size] one-hot
# torch.mm only for 2 dim matrix, but torch.matmul can use to any dim
hidden_layer = torch.matmul(X, self.W) # hidden_layer : [batch_size, embedding_size]
output_layer = torch.matmul(hidden_layer, self.V) # output_layer : [batch_size, voc_size]
return output_layer
model = Word2Vec().to(device)
criterion = nn.CrossEntropyLoss().to(device)
optimizer = optim.Adam(model.parameters(), lr=1e-3)训练
代码语言:javascript复制# Training
for epoch in range(2000):
for i, (batch_x, batch_y) in enumerate(loader):
batch_x = batch_x.to(device)
batch_y = batch_y.to(device)
pred = model(batch_x)
loss = criterion(pred, batch_y)
if (epoch 1) % 1000 == 0:
print(epoch 1, i, loss.item())
optimizer.zero_grad()
loss.backward()
optimizer.step()由于我这里每个词是用的2维的向量去表示,所以可以将每个词在平面直角坐标系中标记出来,看看各个词之间的距离
代码语言:javascript复制for i, label in enumerate(vocab):
W, WT = model.parameters()
x,y = float(W[i][0]), float(W[i][1])
plt.scatter(x, y)
plt.annotate(label, xy=(x, y), xytext=(5, 2), textcoords='offset points', ha='right', va='bottom')
plt.show()完整代码如下:
代码语言:javascript复制'''
code by Tae Hwan Jung(Jeff Jung) @graykode, modify by wmathor
6/11/2020
'''
import torch
import numpy as np
import torch.nn as nn
import torch.optim as optim
import matplotlib.pyplot as plt
import torch.utils.data as Data
dtype = torch.FloatTensor
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
sentences = ["jack like dog", "jack like cat", "jack like animal",
"dog cat animal", "banana apple cat dog like", "dog fish milk like",
"dog cat animal like", "jack like apple", "apple like", "jack like banana",
"apple banana jack movie book music like", "cat dog hate", "cat dog like"]
word_sequence = " ".join(sentences).split() # ['jack', 'like', 'dog', 'jack', 'like', 'cat', 'animal',...]
vocab = list(set(word_sequence)) # build words vocabulary
word2idx = {w: i for i, w in enumerate(vocab)} # {'jack':0, 'like':1,...}
# Word2Vec Parameters
batch_size = 8
embedding_size = 2 # 2 dim vector represent one word
C = 2 # window size
voc_size = len(vocab)
skip_grams = []
for idx in range(C, len(word_sequence) - C):
center = word2idx[word_sequence[idx]] # center word
context_idx = list(range(idx - C, idx)) list(range(idx 1, idx C 1)) # context word idx
context = [word2idx[word_sequence[i]] for i in context_idx]
for w in context:
skip_grams.append([center, w])
def make_data(skip_grams):
input_data = []
output_data = []
for i in range(len(skip_grams)):
input_data.append(np.eye(voc_size)[skip_grams[i][0]])
output_data.append(skip_grams[i][1])
return input_data, output_data
input_data, output_data = make_data(skip_grams)
input_data, output_data = torch.Tensor(input_data), torch.LongTensor(output_data)
dataset = Data.TensorDataset(input_data, output_data)
loader = Data.DataLoader(dataset, batch_size, True)
# Model
class Word2Vec(nn.Module):
def __init__(self):
super(Word2Vec, self).__init__()
# W and V is not Traspose relationship
self.W = nn.Parameter(torch.randn(voc_size, embedding_size).type(dtype))
self.V = nn.Parameter(torch.randn(embedding_size, voc_size).type(dtype))
def forward(self, X):
# X : [batch_size, voc_size] one-hot
# torch.mm only for 2 dim matrix, but torch.matmul can use to any dim
hidden_layer = torch.matmul(X, self.W) # hidden_layer : [batch_size, embedding_size]
output_layer = torch.matmul(hidden_layer, self.V) # output_layer : [batch_size, voc_size]
return output_layer
model = Word2Vec().to(device)
criterion = nn.CrossEntropyLoss().to(device)
optimizer = optim.Adam(model.parameters(), lr=1e-3)
# Training
for epoch in range(2000):
for i, (batch_x, batch_y) in enumerate(loader):
batch_x = batch_x.to(device)
batch_y = batch_y.to(device)
pred = model(batch_x)
loss = criterion(pred, batch_y)
if (epoch 1) % 1000 == 0:
print(epoch 1, i, loss.item())
optimizer.zero_grad()
loss.backward()
optimizer.step()
for i, label in enumerate(vocab):
W, WT = model.parameters()
x,y = float(W[i][0]), float(W[i][1])
plt.scatter(x, y)
plt.annotate(label, xy=(x, y), xytext=(5, 2), textcoords='offset points', ha='right', va='bottom')
plt.show()
